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Giovanni Settanni, Antonino Cattaneo, Paolo Carloni 

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1 Molecular Dynamics Simulations of the NGF-TrkA Domain 5 Complex and Comparison with Biological Data 
Giovanni Settanni, Antonino Cattaneo, Paolo Carloni  Biophysical Journal  Volume 84, Issue 4, Pages (April 2003) DOI: /S (03) Copyright © 2003 The Biophysical Society Terms and Conditions

2 Figure 1 Three-dimensional structure of the complex formed by NGF homodimers (red and blue) and two TrkA domain 5 (orange) (Wiesmann et al., 1999). The encoding of the secondary structural elements (which is that used by Wiesmann et al.) and the N- and C-termini are indicated. Two ligand-receptor regions of contact can be identified. The first (common patch) comprises the four central β-strands and L1 β-hairpin from NGF and the AB, C′D, and EF loops and C-term from TrkA. The common patch comprises residues well conserved in both the neurotrophin and Trk receptor families (Wiesmann et al., 1999). The second region (specific patch, specific for this complex) includes residues from the N-terminus of NGF and from the ABED strand of TrkA. Biophysical Journal  , DOI: ( /S (03) ) Copyright © 2003 The Biophysical Society Terms and Conditions

3 Figure 2 MD of NGF-TrkA complex. (A) RMSDs from the initial conformation of the entire complex (red line), of the TrkA subunits (blue line), of NGF (magenta line), and NGF′ (cyan line). (B) Distances between the centers of mass between TrkA and NGF (red line), TrkA′ and NGF (green line), TrkA and NGF′ (blue line), and TrkA′ and NGF′ (orange line). (C) Comparison between x-ray (red) and MD-averaged (cyan) structures. Only the backbone of one NGF and one TrkA subunit is shown. (D) Comparison between the NGF-TrkA′ (red) and the NGF′-TrkA (cyan) MD-averaged structures. Only the backbone is shown. Regions exhibiting large discrepancies (green circles) are shown at the atomic level (TrkA′, NGF, TrkA, and NGF′ are shown in green, dark green, yellow, and dark yellow, respectively). Biophysical Journal  , DOI: ( /S (03) ) Copyright © 2003 The Biophysical Society Terms and Conditions

4 Figure 3 Comparison between x-ray derived B-factors (A) and those calculated on the basis of the MD simulation (B). The most flexible regions are depicted in green, the most rigid in red. As the color scale is normalized to the range of B-factors, it is different in the two cases. Biophysical Journal  , DOI: ( /S (03) ) Copyright © 2003 The Biophysical Society Terms and Conditions

5 Figure 4 Ligand-receptor electrostatic interactions. (A) Stabilizing long-range interactions are provided by the opposite charges on the receptor (green) and ligand (yellow) (in atomic units). The calculated gas phase values of the dipoles are reported. The effective values of the dipoles are expected to be much smaller because of the screening of the protein complex. (B and C) Electrostatic potential and potential energy obtained by solving the Poisson-Boltzmann equation (Gilson and Honig, 1988). Calculations are carried out on 61 equally spaced conformations from the trajectory and the results are averaged. (B) Electrostatic potential on the NGF and TrkA van der Waals surfaces involved in the formation of the complex. Blue and red represent regions of negative and positive potential, respectively. (C) Electrostatic free energies of binding (ΔGbind) of residues at the NGF-TrkA (upper graph) and NGF-TrkA′ (lower graph) interfaces. Left: Residues belonging to the receptor; right: residues belonging to the ligand. Biophysical Journal  , DOI: ( /S (03) ) Copyright © 2003 The Biophysical Society Terms and Conditions

6 Figure 5 Large-scale motions of the complex. Several properties of the largest eigenvector of the covariance matrix are represented. (A) The eigenvector is represented as a vector field on the Cα atoms of the MD-averaged structure. The red-ended stick departing from every Cα atom is proportional (both in length and direction) to the component of the eigenvector along that atom. Large arrows (blue, NGF; green, TrkA) pictorially represent the sum of the motion of the amino acids of each domain. (B) The moduli of the components represented in (A) are plotted as function of the Cα atoms. β-strand and α-helix conformations are depicted in blue and green, respectively. The labels on the x axis indicate the secondary structure elements and the loops of NGF (Wiesmann et al., 1999). (C) Right: Projection of the trajectory along the eigenvector as a function of time. The nonmonotonic behavior indicates a good sampling of the conformational space and the absence of slow drifts in the simulation. Left: Distribution of the projection. The presence of a double peak suggests the existence of two well-separated ensembles of conformations. (D) According to the analysis of Wriggers and Schulten (1997), this large-scale motion can be visualized as a rotation of the TrkA subunits (in red and gray) around the hinge axis of the complex (also in gray and red). Biophysical Journal  , DOI: ( /S (03) ) Copyright © 2003 The Biophysical Society Terms and Conditions

7 Figure 6 Selected biological and calculated properties of TrkA (top) and of NGF (bottom). (Top) (0) Primary sequences. Residues within 5Å from the hinge axes in the MD-averaged structure have been marked with black background. This set comprises residues from the N- and C-terminus of NGF homodimer, from L1 and L4 loops of NGF and from the AB and EF loops of TrkA. (I) Residues involved in direct (d) or water-mediated indirect (w) hydrogen bond interactions with residues on the opposite surface. (II) Residues characterized by markedly favorable (V) electrostatic free energies (ΔGbind in Fig. 4 C). (III) Residues numbering according to Wiesmann et al. (1999). (IV) Residues belonging to the specific (s) or to the common patch (c) of TrkA, as defined in Wiesmann et al. (1999). (V) Residues whose mutations are known that affect slightly (-) or largely (=, IC50>100) the binding constant (Urfer et al., 1998). (Bottom) (I–IV) Same as A. (V–VI) The residues whose mutations are known to increase (V) or to disrupt the biological function (VI) of NGF are marked with “-” (Ibanez, 1995). Biophysical Journal  , DOI: ( /S (03) ) Copyright © 2003 The Biophysical Society Terms and Conditions

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